DE19607248A1 - Expandable housing for printed circuit boards - Google Patents

Description

The invention relates to an expandable housing for printed circuit boards according to the preamble of claim 1.

In certain applications it is necessary for printed circuit boards to provide an extension for additional circuit boards. This expanse possibility enables the user to correspond to a circuit structure can choose according to his wishes. These expansion options are in particular specially provided for PCs where a circuit board carries the basic circuit and Connectors are provided on an expansion bus, on which additional Liche circuit boards are connectable. The result is a setup with one first circuit board in one plane and several spaced apart arranged circuit boards that are parallel to each other and perpendicular to the first Circuit board run. A housing is required to protect this structure derlich, whose height is at least equal to the height of the plurality of circuit boards corresponds and its width and depth determined by the first circuit board becomes.

The size of the housing is determined by the number of circuit boards that can be connected to the first circuit board, which serves as a carrier circuit board. If this carrier circuit board is at the end relative to the other circuit boards the width of the housing must be at least equal to the length of the carrier PCB. If the carrier circuit board is relative to the other circuit boards Is arranged laterally, the width of the housing must be at least equal to the length the carrier circuit board and at least as long as the longest of the remaining conductors be flat. These dimensions of the case must be observed, even if only a single additional circuit board is connected to the carrier circuit board.  

In another case, the circuit boards have mon in the plane of the circuit boards tated connectors on the flat connectors of another PCB are connectable. The Lei run when plugged together parallel and close to each other. Here it is probably possible to have a housing to be smaller than in the example described above, but it is still as before required to provide a housing that has so much volume so that the maximum number of circuit boards can be accommodated.

In the last example described, the distance between the individual Circuit boards very small, so that cooling problems can occur. Is the Ab stood larger between the individual circuit boards than through the flat connection determined pieces, then problems arise when aligning each other connecting connectors. These misalignments get bigger the more further the distance between adjacent circuit boards. Is the distance low between adjacent circuit boards, then it is difficult to connect to separate pieces of application. Usually screwdrivers are used used, but there is a risk of damaging the circuit boards will.

The task is to design the expandable housing so that the number the circuit boards used are not limited by the housing dimensions is.

This problem is solved with the features of claim 1. Advantageous designs can be found in the subclaims.

According to the invention, there is a housing in which the circuit boards are interconnectable, the size of the housing by the number of scarf tion plates is determined. When assembling and disassembling from the levels Components held circuit boards will not bean the circuit boards speaks, so that there is no risk that circuit boards are damaged.  

Arranged by the removable side gate and on the side of the circuit boards It is possible to make external electrical connections.

The connectors of the circuit boards form an expandable bus, with which the The number of circuit boards to be connected to one another is not limited.

The side walls of each housing are designed to allow cooling air to enter is, however, the circuit boards are protected from the outside.

Exemplary embodiments are explained in more detail below with reference to the drawings.

Show it:

Figure 1 is a side view of two housing parts in the not yet connected to.

. 1A and 1B are partial sectional views of circuit boards receiving structures;

Fig. 2 is a perspective view of a housing portion without a circuit board;

2A shows a section through several housing walls, are a plurality of housing sections when joined together.

Fig. 3 is a perspective view of a housing part;

Fig. 3A is an enlarged view of a Pfei used in the housing parts;

Fig. 3B is a perspective view of a portion of a pillar;

Fig. 4 is a perspective view of several housing parts; and

Fig. 5 is a perspective view of the resulting overall structure of interconnected housing parts.

Referring to FIGS. 1, 2, 3 and 4, a planar member 1 is connected to pillars 3 shown. The flat component contains fastening parts for a printed circuit board 5 , the fastening parts being spacers 7 , into which screws 9 are screwed, which pass through bores in the circuit board 5 . The spacers for the flat component 1 and the pillars 3 are made in one piece from plastic.

The holes for the screws in the printed circuit board have ge slightly oversized to ensure that the Threads of the screws go through the holes without the scarf damaging the plate. Due to the oversize of these holes, it is possible the sequence of tightening the screws and the position of the threads of the screws to choose arbitrarily, with which it is also possible that the exact position one circuit board is different from that relative to the pillars another circuit board.

In order to ensure the exact position of the circuit board, two dowel pins 11 are provided on the flat component, which engage in corresponding holes on the circuit board. The dowel pins 11 , of which only two are required, are injection molded in one piece with the flat component.

Since the dowel pins have an exact position relative to the pillars 3 due to the one-piece construction, on the other hand, the holes in the circuit board represent reference points exactly, the position of the circuit board relative to the pillars 3 is fixed with high accuracy.

It should be noted that other means for the precise positional alignment of the circuit board can be used, for example, it is possible according to Fig. 1A, instead of a hole in the circuit board to provide a circuit board attached to the circuit board ter 13 , in the bore 15 of the pin 11th intervenes.

Alternatively, it is shown in FIG. 1B possible to provide in place of a dowel pin on the planar member includes a dowel pin 17 to the circuit board 5, which engages in a precisely positioned bore 19 on the planar member.

The flat component has a slot 21 , while the circuit board carries a connector Ver, consisting of a socket 23 and a plug 25 , the connector being arranged laterally according to the position of the slot 21 . The connector has long, spaced-apart conductor parts 27 , which make it possible for the connecting pieces of circuit boards arranged at a distance from one another to be electrically connected to one another. Of course, the sockets and the plugs can also be arranged in mirror image to one another. If adjacent circuit boards were not precisely aligned with one another, it would not be possible to establish a perfect connection between the adjacent circuit boards via the pins of the connecting pieces. However, since the connectors are precisely aligned with each other, a precise plug connection results.

The pillars are preferably provided with a hole 29 at one end and with a projecting pin 31 at the other end. The pins and holes are sized so that the pins fit snugly into the hole of the adjacent pillar.

A preferred embodiment of the holes and pins is shown in Fig. 3A, which shows an enlarged view of a pillar. Here, reference is made to FIGS . 2 and 3. FIG. 3 shows the underside of the structure with the pillars, while FIG. 3A shows the perspective view of the top of the pillars. Fig. 2 shows the upper side of the structure, for clarity wherein the circuit board is omitted. The view in FIG. 2 corresponds to that in FIG. 3A.

In this embodiment, the pin 31 is arranged inside a shell 33 , while the hole 29 is arranged inside a cylindrical projection 35 . The bottom 37 of the shell 33 abuts a shoulder 39 of the pillar when the holes 29 of the pillar have received the pins 31 of the adjacent pillar.

The pin 31 may be provided with a key-shaped projection 30 , which engages in a slot 32 on the hole 29 . Using such a structure at one of the corners ensures that the housing sections are not assembled incorrectly. The use of such a structure at two opposite corners or at three or four corners ensures that the user cannot assemble at three corners of the housing structure and then tries to assemble at the fourth corner, breaking off the key-shaped projection.

The pillars preferably have locking devices in order to lock one housing with the next. The Fig. 3A shows a locking assembly consisting of a pawl 41 which engages a slot 43 of the pillar of the adjacent housing, which is arranged in a wall of the shell 33. The pawl is elastic. This can be caused by injection molded slots on the edges of the shell 33 at the end of the pawl. The pawl then has a relatively long arm, whereby the pawl is elastic due to the flexibility of the plastic material.

The assembly of the structure described above is clear from FIG. 1, the same applies to the perspective view according to FIG. 4. The fitting holes of the printed circuit boards are in alignment with the dowel pins 11 for each housing section and the circuit boards lie against the spacers 7 at. The circuit boards are fastened to the spacers 7 by means of screws 9 . At this time, the circuit boards are precisely positioned relative to the pillars 3 .

The pillars of each section are then fitted together by inserting the pins 31 of the pillars of one section into the holes 29 of the adjacent pillar of the next section. The pillars are put together, the Klin ken 41 engage in the interior of the adjacent shell and lock there due to their elasticity with the slots 43 . In this way, the pillars are interlocked.

When the pillars are plugged together, the connectors also snap into place  adjacent circuit boards with each other. Due to the exact location and orientation The circuit boards are guaranteed to be precisely aligned performs even when the connectors are attached to the side of the circuit boards are arranged.

Covers 47 are preferably used to close the entire structure. The upper cover should have shell parts 33 corresponding to the pillars which are arranged at the pillars 3 of the housing sections on which they are placed. The shell parts comprise slots 43 with which the pawls 41 of the pillars engage. A floor cover, not shown, has the pin parts of the pillars 3 which engage in the corresponding holes in the lower housing section.

FIG. 5 shows a multi-housing structure sections. Here the individual sections are locked together and the entire structure is protected by cover 47 . The circuit boards are electrically connected to one another via the connecting pieces. Since the connectors of the circuit boards form a bus for the circuit, the structure forms both an expandable bus and an expandable housing at the same time. The size of the structure and the bus length are limited to the number of circuit boards used, which results in a rational structure.

According to a further exemplary embodiment, a frame 49 is provided on at least three sides of the flat component. The frame shown in FIGS. 2 and 2A extends only three sides. The frame is injection molded together with the flat component and the pillars 3 at the corners.

The frame is preferably formed by a U-shaped component 51 according to FIG. 2A. The U-shaped component consists of an inner leg 53 and an outer leg 55 connected to it . The inner leg 53 has slots 54 or similar openings, while the outer leg 55 has no such openings. The inner leg has a width which corresponds to the height of the pillars 3 , so that when a plurality of housing sections are locked together, the upper edge of the inner leg of one section abuts against the lower edge of the inner leg of the next section. The outer leg is angled from its edge where it is connected to the inner leg.

The result is shown in Fig. 2A and Fig. 5. Cooling air can penetrate through the slots 54 into the air duct between the legs 55 , as shown by the arrows 57 . Due to the angle of the outer leg relative to the underside of the outer leg of the housing section immediately above, air can get into the environment or air from the environment can enter the area of the circuit boards via the slots 54 , thereby cooling them. However, since the outer legs have no holes, they provide a visual barrier that prevents a person from looking inside the housing structure. As a result of this privacy shield as well as because of the angle and the small gap width between the outer legs 55 of adjacent housing sections, it is prevented that a person is able to penetrate into the interior of the housing structure.

A three-wall structure has been described above, but it is possible to provide a structure with four walls. The fourth wall can a hole can be provided, into which a plug can be inserted, which with a corresponding socket of a circuit board can be brought into engagement.

According to the Fig. 4 may alternatively be a removable gate 59 are used. This gate is held in slots 61 which are formed on mutually opposite surfaces of the pillars 3 on the fourth side.

This gate consists of a rigid rectangular part made of plastic or metal and is inserted with its short sides into the slots 61 . When assembled as shown in FIG. 5, these gates prevent access to the circuit boards.

The gate can be adapted to the requirements of the circuit boards used in the special housing section. For example, if the circuit board has no side connectors, then a gate is used in this section that has no holes. However, if the circuit board has a side connector, then a gate is used that has one or more holes, such as hole 63 . In this way, all housing sections can be constructed identically and can be used for all circuit boards univer sell. It is not necessary to use special injection molding structures to adapt them to the various configurations of the circuit boards.

The top and bottom covers in connection with the walls result a protected, expandable structure that can be adapted to the respective needs is. The bottom cover can be one or more keyhole shaped Boh stanchions to facilitate hanging on a wall.

In the preferred embodiment, pillars have been described. These are on the Corners arranged. However, it is also possible to place the pillars in other places watch.

Claims (18)

1. Expandable housing for printed circuit boards, which are arranged in parallel and at a distance from one another and which can be electrically connected to one another via plug connections, characterized by a first level component ( 1 ), the dimensions of which correspond at least to those of a circuit board ( 5 ) At least one side of the first flat component ( 1 ), first pillars ( 3 ) are provided, which protrude at right angles from the first flat component ( 1 ), on the first flat component ( 1 ) protruding fastening means for fastening a first circuit board ( 5 ) at a distance to the first flat component ( 1 ) are provided, between the first flat component ( 1 ) and the first circuit board ( 5 ) a fitting connection is provided which precisely positions the first circuit board ( 5 ) relative to the first pillars ( 3 ), a second the first flat component ( 1 ) is the same flat component ( 1 ) and the flat components ( 1 ) are above them Pillars ( 3 ) can be connected to one another. 2. Housing according to claim 1, characterized in that the Paßvorrich device consists of at least two spaced dowel pins ( 11 ) which are perpendicular to the planar component ( 1 ) in the same Rich direction as the pillar ( 3 ) and in holes engage the circuit board ( 5 ). 3. Housing according to claim 1, characterized in that at least two spaced dowel pins ( 11 ) are provided, which extend at right angles to the flat component ( 1 ) in the same direction as the pillars ( 3 ) and which in bores ( 15 ) of passport holders ( 13 ) on the circuit board ( 5 ). 4. Housing according to claim 1, characterized in that on the circuit board ( 5 ) at least two spaced dowel pins ( 17 ) are provided, which are perpendicular to the circuit board ( 5 ) and engage in holes on the flat component. 5. Housing according to claim 1, characterized in that the flat construction parts ( 1 ) aligned slots ( 21 ), within the slot area, the circuit boards ( 5 ) carry connectors that consist of a socket ( 23 ) and a plug ( 25 ) exist, the plugs ( 25 ) extend through the slots ( 21 ) and the plug ( 25 ) of one circuit board ( 5 ) can be connected to the socket ( 23 ) of the adjacent circuit board ( 5 ). 6. Housing according to one of claims 1 to 5, characterized in that with the upper and lower sides of the pillars ( 3 ) covers ( 47 ) can be connected. 7. Housing according to one of claims 1 to 6, characterized in that the pillars ( 3 ) on one side pins ( 31 ) and on the other side have holes ( 29 ), the pins ( 31 ) of a pillar ( 3rd ) engage in the holes ( 29 ) adjacent pillars ( 3 ) with a snug fit. 8. Housing according to claim 7, characterized in that the pins ( 31 ) have a key-shaped projection ( 30 ) and the slots ( 29 ) are formed like a keyhole. 9. Housing according to one of claims 1 to 8, characterized in that the flat components ( 1 ) are substantially rectangular and the pillars ( 3 ) are arranged in the corners of the flat components ( 1 ). 10. Housing according to one of claims 1 to 9, characterized in that the pillars ( 3 ) of adjacent flat components ( 1 ) can be locked together. 11. Housing according to claim 10, characterized in that the pillars ( 3 ) on the one hand a pawl ( 41 ) and on the other hand have a slot ( 43 ) with which the pawl ( 41 ) of an adjacent pillar ( 3 ) latches. 12. Housing according to claim 10 or 11, characterized in that in each case three pillars ( 3 ) of a flat component ( 1 ) have locking means. 13. Housing according to one of claims 1 to 12, characterized in that a frame ( 49 ) is provided on at least three sides of each flat component ( 1 ), which runs between the pillars ( 3 ) and a height equal to the height of a pillar ( 3 ). 14. Housing according to claim 13, characterized in that a removable gate ( 59 ) is arranged on the fourth side of each flat component ( 1 ), the height of which corresponds to the height of the frame ( 49 ). 15. Housing according to claim 14, characterized in that the thin, stiff, fenced rectangular gate ( 59 ) in slots ( 61 ) opposite pillars ( 3 ) can be inserted. 16. Housing according to claim 14 or 15, characterized in that circuit boards ( 5 ) in the region of the gate ( 59 ) have sockets and the gates ( 59 ) in the region of the sockets are provided with openings ( 63 ) through which the sockets are accessible are. 17. Housing according to one of claims 13 to 16, characterized in that each arm ( 51 ) of the frame ( 49 ) has a substantially U-shaped cross section. 18. Housing according to claim 17, characterized in that the arms ( 51 ) have an inner, with slots ( 54 ) provided leg ( 53 ) which is at right angles to the planar component ( 1 ), and an outer leg ( 55 ) , wherein the outer legs ( 55 ) of adjacent components ( 1 ) at a distance from each other.